High frequency module, board equipped with antenna, and high frequency circuit board

ABSTRACT

A first board includes a first ground plane, a first ground land, a first transmission line, and a first signal land connected to the first transmission line, wherein the first ground land and the first signal land are formed on the same surface. A second board includes a second ground plane, a second ground land, a second transmission line, and a second signal land connected to the second transmission line, wherein the second ground land and the second signal land are formed on a surface opposing the first board. The second ground land and the second signal land oppose the first ground land and the first signal land, respectively. A conduction member connects the first ground land and the second ground land. The first signal land and the second signal land are connected by capacitance coupling without using any conductor.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a Continuation of U.S. patent application Ser. No. 15/705,927filed on Sep. 15, 2017, which claims priority from Japanese PatentApplication No. 2016-181093 filed on Sep. 16, 2016. The contents ofthese applications are incorporated herein by reference in theirentireties.

BACKGROUND OF THE DISCLOSURE Field of the Disclosure

The present disclosure relates to high frequency modules, boardsequipped with an antenna, and high frequency circuit boards.

Description of the Related Art

A connection structure in which lands of two high frequency circuitcomponents are connected to each other with solder bumps or the likeinterposed therebetween is well-known.

Japanese Unexamined Patent Application Publication No. 2008-205975discloses a device in which a high frequency semiconductor integratedcircuit (RFIC) is mounted on a board with solder bumps interposedtherebetween. A matching circuit is configured using parasiticcapacitance that is formed between dummy bump pads of the RFIC and aground layer of the RFIC. By performing wiring on the board side tointerconnect the dummy bump pads, a capacitor with desired capacitancecan be configured through combining the pieces of the parasiticcapacitance in the dummy bump pad portions. Adjusting the capacitance ofthe capacitor makes it possible to obtain impedance matching.

Japanese Unexamined Patent Application Publication No. 2011-135112discloses a connection structure in which a semiconductor integratedcircuit that includes ground electrodes, power supply electrodes, andsignal electrodes is mounted on a wiring board with bumps interposedtherebetween. In an area where the signal electrodes are disposedsandwiching the ground electrode and the power supply electrode, thesignal electrodes are connected to each other with a bump; in an areawhere the power supply electrode and the ground electrode are positionedadjacent to each other, the power supply electrodes are connected toeach other with a bump, and the ground electrodes are also connected toeach other with a bump; the power supply electrodes and groundelectrodes other than those mentioned above are not connected. With thestated configuration, degradation in electric characteristics due tocoupling capacitance between the adjacent bumps is prevented.

Japanese Unexamined Patent Application Publication No. 2004-15160discloses a module equipped with an antenna that includes a slot antennaformed in one surface of a base body, a signal processing circuit whichperforms at least one of reception and transmission operations using theslot antenna, and a shield conductor for covering surfaces of the basebody. A capacitor, an inductor, and the like are disposed inside thebase body.

In the connection structure described in Japanese Unexamined PatentApplication Publication No. 2008-205975, dummy bump pads need to beprovided in the RFIC in advance so as to configure a capacitor for theimpedance matching. With the connection structure described in JapaneseUnexamined Patent Application Publication No. 2011-135112, although thedegradation in electric characteristics due to coupling capacitancebetween the adjacent bumps is prevented, any measure to improvetransmission characteristics between the semiconductor integratedcircuit and the wiring board is not taken. The structure described inJapanese Unexamined Patent Application Publication No. 2004-15160 is astructure in which a capacitor and the like are provided inside the basebody, and is different from a structure in which connections are carriedout using solder bumps or the like.

BRIEF SUMMARY OF THE DISCLOSURE

An object of the present disclosure is to provide a high frequencymodule capable of suppressing the degradation in transmissioncharacteristics between two high frequency components.

The high frequency module according to a first aspect of the presentdisclosure includes:

a first board which has a first ground plane, a first ground landconnected to the first ground plane, a first transmission line, and afirst signal land connected to the first transmission line, and in whichthe first ground land and the first signal land are formed on the samesurface;

a second board which has a second ground plane, a second ground landconnected to the second ground plane, a second transmission line, and asecond signal land connected to the second transmission line, and inwhich the second ground land and the second signal land are formed on asurface opposing the first board and respectively oppose the firstground land and the first signal land; and

a conduction member for connecting the first ground land and the secondground land,

wherein the first signal land and the second signal land are connectedby capacitance coupling without using any conductor.

A high frequency signal is transmitted between the first board and thesecond board through capacitance formed between the first signal landand the second signal land. Because the high frequency signal istransmitted to the first transmission line and the second transmissionline without using a large-sized solder bump or the like, reflection ofthe high frequency signal due to discontinuity of characteristicimpedance or the like is unlikely to be generated. This makes itpossible to improve transmittance characteristics for the high frequencysignal between the first board and the second board. In addition,because the first transmission line in the first board and the secondtransmission line in the second board are connected by capacitancecoupling, a low frequency noise leakage in a direction from the firsttransmission line to the second transmission line or in the reversedirection can be suppressed.

The high frequency module according to a second aspect of the presentdisclosure is configured such that, in addition to the configuration ofthe high frequency module according to the first aspect:

the first board further includes a radiation element that is connectedto the first signal land with the first transmission line interposedtherebetween; and

a high frequency circuit element is mounted on the second board and isconnected to the second signal land with the second transmission lineinterposed therebetween.

Transmittance characteristics for the high frequency signal from thehigh frequency circuit element to the radiation element or from theradiation element to the high frequency circuit element can be improved.It can be suppressed that low frequency noise superposed on the secondtransmission line inside the second board on which the high frequencycircuit element is mounted is transmitted to the radiation element.

The high frequency module according to a third aspect of the presentdisclosure is configured such that, in addition to the configurationaccording to the first or second aspect:

areas of the first signal land and the second signal land opposing eachother are different from each other, and one of the above lands isencompassed in the other of the lands in a plan view.

In the case where one of the first and second signal lands isencompassed in the other thereof, even if a positional shift between thefirst board and the second board occurs, the capacitance of a capacitorconfigured by the first signal land and the second signal land ismaintained to be constant. This makes it possible to suppress avariation in transmittance characteristics for the high frequencysignal.

The high frequency module according to a fourth aspect of the presentdisclosure is configured such that, in addition to the configuration ofthe high frequency module according to the first through third aspects:

the first board includes a first stub provided on a connection portionbetween the first transmission line and the first signal land.

The high frequency module according to a fifth aspect of the presentdisclosure is configured such that, in addition to having theconfiguration of the high frequency module according to the firstthrough fourth aspects:

the second board includes a second stub provided on a connection portionbetween the second transmission line and the second signal land.

Providing the first stub or the second stub makes it possible to obtainthe impedance matching.

The high frequency module according to a sixth aspect of the presentdisclosure is configured such that, in addition to the configuration ofthe high frequency module according to the first through fifth aspects:

the first board includes a first protection film that is provided on asurface opposing the second board, exposes the first ground land, andcovers the first signal land; and

the second board includes a second protection film that is provided on asurface opposing the first board, exposes the second ground land, andcovers the second signal land.

Because the first signal land is covered with the first protection filmand the second signal land is covered with the second protection film,these lands can be protected before bonding the first board and thesecond board. Because the first signal land and the second signal landare not connected with a conductor interposed therebetween, the couplingbetween the first signal land and the second signal land is notobstructed by any of the first protection film and the second protectionfilm.

The board equipped with an antenna according to a seventh aspect of thepresent disclosure includes:

a first dielectric substrate;

a radiation element provided on the first dielectric substrate;

a first signal land provided on the first dielectric substrate andconnected to the radiation element;

a first ground plane provided in or on the first dielectric substrate;

a first ground land that is provided along with the first signal land onthe same surface of the first dielectric substrate and is connected tothe first ground plane; and

a first protection film that is disposed on the surface of the firstdielectric substrate where the first signal land is provided, covers thefirst signal land, and exposes the first ground land.

Because the first signal land is covered with the first protection film,the first signal land can be protected before bonding the first board toanother board. The first signal land can be connected to a land of acorresponding board by capacitance coupling.

The high frequency circuit board according to an eighth aspect of thepresent disclosure includes:

a second dielectric substrate;

a high frequency circuit element mounted on the second dielectricsubstrate;

a second signal land provided on the second dielectric substrate andconnected to the high frequency circuit element;

a second ground plane provided in or on the second dielectric substrate;

a second ground land that is provided along with the second signal landon the same surface of the second dielectric substrate and is connectedto the second ground plane; and

a second protection film that is disposed on the surface of the seconddielectric substrate where the second signal land is provided, coversthe second signal land, and exposes the second ground land.

Because the second signal land is covered with the second protectionfilm, the second signal land can be protected before bonding the secondboard to another board. The second signal land can be connected to aland of a corresponding board by capacitance coupling.

A high frequency signal is transmitted between the first board and thesecond board through capacitance formed between the first signal landand the second signal land. Because the high frequency signal istransmitted to the first transmission line and the second transmissionline without using a large-sized solder bump or the like, reflection ofthe high frequency signal due to discontinuity of characteristicimpedance or the like is unlikely to be generated. This makes itpossible to improve the transmittance characteristics for the highfrequency signal between the first board and the second board. Inaddition, because the first transmission line in the first board and thesecond transmission line in the second board are connected bycapacitance coupling, a low frequency noise leakage in a direction fromthe first transmission line to the second transmission line or in thereverse direction can be suppressed.

Other features, elements, characteristics and advantages of the presentdisclosure will become more apparent from the following detaileddescription of preferred embodiments of the present disclosure withreference to the attached drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a cross-sectional view of a high frequency module according toa first embodiment;

FIG. 2A and FIG. 2B are views each illustrating planar arrangement ofparts of signal lands and ground lands of a board equipped with anantenna as well as parts of ground lands and signal lands of a highfrequency circuit board according to a second embodiment;

FIG. 3A and FIG. 3B are respectively a perspective view and across-sectional view of a high frequency signal transmission pathconnecting an RFIC and a radiation element of a high frequency moduleaccording to a third embodiment;

FIG. 4 is a graph indicating a simulation result of transmittancecharacteristics from an RFIC land to a leading end of a transmissionline;

FIG. 5 is a graph indicating a simulation result of transmittancecharacteristics from an RFIC land to a leading end of a transmissionline according to a fourth embodiment; and

FIG. 6A and FIG. 6B are respectively a perspective view and across-sectional view of a high frequency signal transmission pathconnecting an RFIC and a radiation element of a high frequency moduleaccording to a fifth embodiment.

DETAILED DESCRIPTION OF THE DISCLOSURE First Embodiment

A high frequency module 1 according to a first embodiment will bedescribed with reference to FIG. 1. The high frequency module 1according to the first embodiment includes a board equipped with anantenna 10 and a high frequency circuit board 30 mounted on the boardequipped with an antenna 10.

FIG. 1 is a cross-sectional view of the high frequency module 1according to the first embodiment. The board equipped with an antenna 10includes a dielectric substrate 11. On one surface (hereinafter,referred to as an upper surface) of the dielectric substrate 11, thereare provided a plurality of signal lands 21, a plurality of ground lands22, a power supply land 23, and a connector 25. On the other surface(hereinafter, referred to as a lower surface) of the dielectricsubstrate 11, a plurality of radiation elements 13 are provided. Anoperation frequency band of the radiation element 13 is a millimeterwave band, for example. A ground plane 14 is disposed on a surface or atthe inside of the dielectric substrate 11. The signal land 21 isprovided corresponding to the radiation element 13, and a transmissionline 15 provided inside the dielectric substrate 11 connects the signalland 21 and the radiation element 13 that correspond to each other. Theground plane 14 is connected to the ground land 22.

A coaxial cable serving as both a signal line and a power supply line isconnected to the connector 25. A DC power supply, a local signal, anintermediate frequency signal, and the like are supplied to the boardequipped with an antenna 10 through the coaxial cable. A shieldconductor of the coaxial cable is connected to the ground plane 14 viathe connector 25. The center conductor of the coaxial cable is connectedto the power supply land 23 via the wiring inside the dielectricsubstrate 11.

The upper surface of the dielectric substrate 11 is covered with aninsulative protection film 26 that is formed of solder resist or thelike. The protection film 26 covers the signal land 21, but exposes theground land 22 and the power supply land 23. For example, openings areprovided in the protection film 26 at the positions corresponding to theground land 22 and the power supply land 23.

The high frequency circuit board 30 includes a dielectric substrate 31.On one surface (hereinafter, referred to as a lower surface) of thedielectric substrate 31, there are provided a plurality of signal lands41, a plurality of ground lands 42, and a power supply land 43. On theother surface (hereinafter, referred to as an upper surface) of thedielectric substrate 31, a high frequency integrated circuit element(RFIC) 32 and a high frequency component 33 are mounted. A ground plane34 is disposed on a surface or at the inside of the dielectric substrate31. The ground plane 34 is connected to the ground land 42 and is alsoconnected to a ground terminal of the RFIC 32. Transmission lines 35provided inside the dielectric substrate 31 respectively connect theplurality of signal lands 41 and a plurality of signal terminals of theRFIC 32.

The lower surface of the dielectric substrate 31 is covered with aninsulative protection film 46 that is formed of solder resist or thelike. The protection film 46 covers the signal lands 41, but exposes theground lands 42 and the power supply land 43. For example, openings areprovided in the protection film 46 at the positions corresponding to theground lands 42 and the power supply land 43.

The high frequency circuit board 30 is mounted on the board equippedwith an antenna 10 in a posture such that its lower surface opposes theboard equipped with an antenna 10. The power supply land 23 of the boardequipped with an antenna 10 and the power supply land 43 of the highfrequency circuit board 30 are connected with a conduction member 50such as a solder bump or the like, and the ground land 22 of the boardequipped with an antenna 10 and the ground land 42 of the high frequencycircuit board 30 are connected with the conduction member 50 such as asolder bump or the like.

The plurality of signal lands 21 of the board equipped with an antenna10 oppose the plurality of signal lands 41 of the high frequency circuitboard 30 so that the mutually corresponding signal lands 21 and 41oppose each other while being distanced from each other, whereby thesignal lands 21 and signal lands 41 are connected by capacitancecoupling without using any conductor. The stated capacitance isdetermined by the size of the signal lands 21 and 41, an intervaltherebetween, and a dielectric constant of a space between the signallands 21 and 41. An underfill material, for example, is filled intobetween the board equipped with an antenna 10 and the high frequencycircuit board 30.

A shield 48 for covering the RFIC 32 and the high frequency component 33is disposed on the upper surface of the dielectric substrate 31. Forexample, it is possible to seal the RFIC 32 as well as the highfrequency component 33 with resin and form the shield 48 on a surface ofthe sealing resin. A shield cap made of metal may be used as the shield48.

The signal terminals of the RFIC 32 are each connected to the radiationelement 13 with the transmission line 35 inside the dielectric substrate31, the capacitor generated between the signal lands 21 and 41, and thetransmission line 15 inside the dielectric substrate 11 interposedtherebetween.

Effect of First Embodiment

Next, an excellent effect of the high frequency module according to thefirst embodiment will be described.

In general, a thinned microstrip line with a thickness of about 50 μm isused as a transmission line of a millimeter wave band (wave length is noless than about 1 mm and no more than about 10 mm; frequency is no lessthan about 30 GHz and no more than about 300 GHz). In contrast, thesignal lands 21 and 41, ground lands 22 and 42, and power supply lands23 and 43 have a dimension of about several hundred μm. These lands areeach formed in a substantially circular shape with a diameter of about300 μm, for example. It is not preferable to make these lands furthersmaller from the standpoint of mechanical strength of bonding betweenthe board equipped with an antenna 10 and the high frequency circuitboard 30.

In a case of the signal lands 21 and 41 being connected to each otherwith a solder bump or the like, a difference between the width of thetransmission line and the dimension of the land, solder bump, or thelike cannot be ignored in the transmission of millimeter wave band. Forexample, a difference in dimension causes discontinuity in thecharacteristic impedance. The transmission characteristics are degradeddue to the occurrence of reflection of the millimeter wave signal at adiscontinuity point of the characteristic impedance.

In the first embodiment, the transmission line 15 inside the boardequipped with an antenna 10 and the transmission line 35 inside the highfrequency circuit board 30 are connected by capacitance coupling,whereby the degradation in the transmission characteristics due to adimensional discontinuity of joint portions can be lessened.

Although the high frequency circuit board 30 is shielded by the shield48, a power supply signal to drive the RFIC 32, DC noise, a local signalhaving a lower frequency than the millimeter wave band (in general, noless than about 1 GHz and no more than about 7.5 GHz), an intermediatefrequency signal (in general, no less than about 10 GHz and no more thanabout 15 GHz), or the like are superposed on the transmission line 35 ofthe millimeter wave band. In a configuration in which the signal lands21 and 41 are connected with a solder bump or the like, theabove-mentioned signals superposed on the transmission line 35undesirably are leaked as noise to the board equipped with an antenna10.

In the first embodiment, because the transmission line 35 inside thehigh frequency circuit board 30 and the transmission line inside theboard equipped with an antenna 10 are connected by capacitance coupling,the leakage of low frequency noise from the high frequency circuit board30 to the board equipped with an antenna 10 can be suppressed. Thismakes it possible to suppress the radiation of low frequency noise fromthe radiation element 13.

In a case of employing the configuration in which the signal lands 21and 41 are connected with a solder bump or the like, the signal lands 21and 41 need to be exposed. In the first embodiment, the signal lands 21of the board equipped with an antenna 10 are covered with the protectionfilm 26, and the signal lands 41 of the high frequency circuit board 30are covered with the protection film 46. With this, the signal lands 21and 41 can be also protected during a processing stage after havingformed the protection films 26 and 46.

Variation on First Embodiment

Next, a variation on the first embodiment will be described. In thefirst embodiment, although the high frequency circuit board 30 is bondedto the board equipped with an antenna 10 using solder bumps or the like,other two high frequency circuit boards may be bonded. Also in thiscase, it is sufficient that a ground land and a power supply land of oneboard are respectively connected to a ground land and a power supplyland of the other board with solder bumps or the like interposedtherebetween, and signal lands of the respective boards are connected toeach other by capacitance coupling without using any conductor.

Second Embodiment

Next, a high frequency module according to a second embodiment will bedescribed with reference to FIG. 2A and FIG. 2B. Hereinafter,description of the same configurations as those of the high frequencymodule according to the first embodiment will be omitted.

FIG. 2A is a view illustrating planar arrangement of parts of the signallands 21 and ground lands 22 of the board equipped with an antenna 10(FIG. 1) as well as parts of the signal lands 41 and ground lands 42 ofthe high frequency circuit board 30. For example, four ground lands 22are so disposed as to surround the signal land 21. The signal land 21 islarger in size than the ground land 22. For example, the signal land 21is formed in a substantially circular shape with a diameter of about 400μm, while the ground land 22 is formed in a substantially circular shapewith a diameter of about 300 μm.

The signal lands 41 and ground lands 42 of the high frequency circuitboard 30 (FIG. 1) are respectively disposed at the positionscorresponding to the signal lands 21 and ground lands 22 of the boardequipped with an antenna 10. The size and shape of the ground land 42 ofthe high frequency circuit board 30 are the same as those of the groundland 22 of the board equipped with an antenna 10. The signal land 41 ofthe high frequency circuit board 30 is smaller in size than the signalland 21 of the board equipped with an antenna 10. For example, thesignal land 41 of the high frequency circuit board 30 is formed in asubstantially circular shape with a diameter of about 300 μm. Thiscauses the signal land 41 of the high frequency circuit board 30 to beencompassed in the signal land 21 of the board equipped with an antenna10 in a plan view.

FIG. 2B illustrates a state in which the high frequency circuit board 30is mounted as being shifted relative to the board equipped with anantenna 10. The center of the signal land 41 of the high frequencycircuit board 30 is shifted relative to the center of the signal land 21of the board equipped with an antenna 10. Note that, however, if theamount of shift falls within a tolerable range, the state in which thesignal land 41 of the high frequency circuit board 30 is encompassed inthe signal land 21 of the board equipped with an antenna 10 ismaintained.

Effect of Second Embodiment

Next, an excellent effect of the second embodiment will be described.Even in the case where the high frequency circuit board 30 is mounted asbeing shifted relative to the board equipped with an antenna 10, if theamount of shift falls within the tolerable range, an area of a portionwhere the signal lands 21 and 41 overlap with each other is unchanged.This makes it possible to maintain capacitance between the signal lands21 and 41 to be constant. As a result, a variation in transmissioncharacteristics among individual high frequency modules 1 can belessened.

Variation on Second Embodiment

Although each of FIGS. 2A and 2B describes an example in which thesignal land 21 of the board equipped with an antenna 10 is larger thanthe signal land 41 of the high frequency circuit board 30, the signalland 41 may be larger than the signal land 21. For example, the signalland 21 of the board equipped with an antenna 10 may be formed in asubstantially circular shape with a diameter of about 300 μm, while thesignal land 41 of the high frequency circuit board 30 may be formed in asubstantially circular shape with a diameter of about 400 μm.

Third Embodiment

Next, a high frequency module according to a third embodiment will bedescribed with reference to FIGS. 3A, 3B, and 4. Hereinafter,description of the same configurations as those of the first and secondembodiments will be omitted.

FIG. 3A and FIG. 3B are respectively a perspective view and across-sectional view of a high frequency signal transmission pathconnecting the RFIC 32 and the radiation element 13 (FIG. 1). Note thatthe upper side and lower side in FIG. 1 are inverted in the drawings ofFIGS. 3A and 3B. That is, the high frequency circuit board 30 isillustrated on the lower side while the board equipped with an antenna10 is illustrated on the upper side in each of the drawings. Further,the ground plane is not illustrated in FIG. 3A. The RFIC 32 is mountedon the high frequency circuit board 30 with solder bumps or the likeinterposed therebetween. An RFIC land 38 of the high frequency circuitboard 30 is connected to a signal terminal of the RFIC with a solderbump interposed therebetween.

The high frequency circuit board 30 includes the ground planes 34 thatare respectively provided on the surfaces on both sides thereof, andfour layers configured of the ground planes 34 that are disposed in aninner layer thereof. The high frequency circuit board 30 furtherincludes the signal land 41 and the ground land 42 provided on a surfaceon the opposite side to the surface on which the RFIC 32 is mounted. Theground land 42 is configured by a part of the ground plane 34 formed onthe surface.

The signal land 41 is connected to the signal terminal of the RFIC 32with a plurality of conductor vias 37 as well as a plurality of innerlayer lands 36 disposed in the inner layer of the high frequency circuitboard 30, and the RFIC land 38 interposed therebetween. The plurality ofconductor vias 37 and the plurality of inner layer lands 36 function asthe transmission line 35 (FIG. 1).

The board equipped with an antenna 10 includes the signal land 21provided on a surface opposing the high frequency circuit board 30, thetransmission line 15 disposed in an inner layer thereof, and the groundplane 14 provided on the surface opposing the high frequency circuitboard 30. A part of the ground plane 14 is used as the ground land 22.There are also provided the ground planes 14 on both sides of thetransmission line 15 so that the transmission line 15 has a coplanarwaveguide structure equipped with a ground. The radiation element 13(FIG. 1) is connected to a leading end of the transmission line 15.

The transmission line 15, at one end thereof, is connected to the signalland 21 with a conductor via 16 interposed therebetween. An open stub 17is disposed on a connection portion between the transmission line 15 andthe signal land 21. The open stub 17 is disposed, for example, in thesame layer as the transmission line 15, and extends, taking the signalland 21 as a starting point, in a direction opposite to the side of thetransmission line 15.

A portion serving as the ground land 42 of the ground plane 34 providedon the surface of the high frequency circuit board 30 opposing the boardequipped with an antenna 10 and a portion serving as the ground land 22of the ground plane 14 provided on the surface of the board equippedwith an antenna 10 opposing the high frequency circuit board 30 areconnected to each other by each of a plurality of conduction members 50,for example, by four conduction members 50. The conduction members 50are so disposed as to surround the signal lands 21 and 41 in a planview. An underfill material 51 is filled into between the high frequencycircuit board 30 and the board equipped with an antenna 10.

FIG. 4 is a graph indicating a simulation result of transmittancecharacteristics S21 from the RFIC land 38 to the leading end of thetransmission line 15 (FIGS. 3A and 3B). The horizontal axis representsthe frequency in units of “GHz”, while the vertical axis represents thetransmittance characteristics S21 in units of “dB”. A solid line in FIG.4 indicates the transmittance characteristics S21 of the high frequencymodule according to the third embodiment shown in FIGS. 3A and 3B, and abroken line indicates transmittance characteristics S21 of a highfrequency module according to a reference example. In the high frequencymodule according to the reference example, the signal lands 21 and 41are connected with a conduction member, and the open stub 17 is notprovided.

Hereinafter, the configuration of the high frequency module according tothe third embodiment, which was a simulation target, will be described.A desired electrostatic capacity of a capacitor configured by the signallands 21 and 41 is about 50 fF. In order to meet this requirement, aplanar shape of each of the signal lands 21 and 24 was madesubstantially circular having a diameter of about 300 μm, a relativedielectric constant of a space between the signal lands 21 and 41 wasset to be about four, an interval between the signal lands 21 and 41 wasset to be about 50 μm, impedance of the open stub was set to be about50Ω, and an electrical length of the open stub was set to be about 0.3times the wave length of a signal of about 60 GHz.

Effect of Third Embodiment

As shown in FIG. 4, it is understood that the high frequency moduleaccording to the third embodiment can obtain more favorabletransmittance characteristics S21 than the high frequency moduleaccording to the reference example in a frequency band of no less thanabout 57 GHz and no more than about 66 GHz that is used in thecommunications of the Wigig standards. Further, the high frequencymodule according to the third embodiment exhibits rejectioncharacteristics of no less than about −10 dB in a frequency region lowerthan about 50 GHz.

As can be understood from the simulation result shown in FIG. 4, theconfiguration in which the signal lands 21 and 41 are not connected witha conduction member makes it possible to improve the transmittancecharacteristics in the frequency band of no less than about 57 GHz andno more than about 66 GHz, and improve the rejection characteristicsagainst low frequency noise in a frequency region lower than the abovefrequency band. Further, providing the open stub 17 makes it possible toobtain the impedance matching.

Fourth Embodiment

Next, a high frequency module according to a fourth embodiment will bedescribed with reference to FIG. 5. Hereinafter, description of the sameconfigurations as those of the first through third embodiments will beomitted.

In the high frequency module according to the fourth embodiment, a shortstub is provided in place of the open stub 17 of the high frequencymodule according to the third embodiment (FIGS. 3A and 3B). Impedance ofthe short stub is about 50Ω, and an electrical length thereof is about0.75 times the wave length of a signal of about 60 GHz. Otherconfigurations are the same as those of the high frequency moduleaccording to the third embodiment shown in FIGS. 3A and 3B.

FIG. 5 is a graph indicating a simulation result of transmittancecharacteristics S21 from the RFIC land 38 to the leading end of thetransmission line 15. The horizontal axis represents the frequency inunits of “GHz”, while the vertical axis represents the transmittancecharacteristics S21 in units of “dB”. A solid line in FIG. 5 indicatesthe transmittance characteristics S21 of the high frequency moduleaccording to the fourth embodiment, and a broken line indicatestransmittance characteristics S21 of a high frequency module accordingto a reference example. The transmittance characteristics S21 of thehigh frequency module according to the reference example are the same asthose shown in FIG. 4.

It is understood that the high frequency module according to the fourthembodiment can also obtain more favorable transmittance characteristicsS21 than the high frequency module according to the reference example inthe frequency band of no less than about 57 GHz and no more than about66 GHz that is used in the communications of the Wigig standards.Further, the high frequency module according to the fourth embodimentalso exhibits more favorable rejection characteristics than the highfrequency module according to the reference example in a frequencyregion lower than about 50 GHz.

In the fourth embodiment, because the short stub is used in place of theopen stub, high electro-static discharge (ESD) resistance can beobtained.

It can be understood, by comparing FIG. 4 with FIG. 5, that theemployment of the short stub rather than the open stub is preferable inthe case where the leakage of low frequency noise of about 50 GHz, whichis slightly lower than the Wigig standards frequency band, needs to besuppressed. It can be understood that the employment of the open stubrather than the short stub is preferable so as to obtain an effect ofnoise leakage suppression across the entire frequency region lower thanthe Wigig standards frequency band.

Fifth Embodiment

Next, a high frequency module according to a fifth embodiment will bedescribed with reference to FIG. 6A and FIG. 6B. Hereinafter,description of the same configurations as those of the first throughfourth embodiments will be omitted.

FIG. 6A and FIG. 6B are respectively a perspective view and across-sectional view of a high frequency signal transmission pathconnecting the RFIC 32 and the radiation element 13. Although, in thethird embodiment, the open stub 17 is provided to the transmission line15 inside the board equipped with an antenna 10 (FIGS. 3A and 3B), anopen stub 18 is provided on a connection portion between thetransmission line 35 inside the high frequency circuit board 30 (FIG. 1)and the signal land 41 in the fifth embodiment. Further, like in thefourth embodiment, a short stub instead of the open stub 18 may beprovided. The same effects as those of the third or fourth embodimentcan be obtained in the fifth embodiment as well.

It should be understood that the above-described embodiments areillustrative only, and that configurations described in differentembodiments can partly replace each other or be combined as well. Sameaction effects brought by the same configurations in the plurality ofembodiments are not successively described in each of the embodiments.Further, the present disclosure is not limited to the above-describedembodiments. For example, it will be apparent to those skilled in theart that various kinds of changes, improvements, combinations, and so oncan be carried out.

While preferred embodiments of the disclosure have been described above,it is to be understood that variations and modifications will beapparent to those skilled in the art without departing from the scopeand spirit of the disclosure. The scope of the disclosure, therefore, isto be determined solely by the following claims.

What is claimed is:
 1. A high frequency module comprising: a first boardhaving a first ground plane, a first ground land connected to the firstground plane, a first transmission line, and a first signal landconnected to the first transmission line, wherein the first ground landand the first signal land are located on a same surface; a second boardhaving a second ground plane, a second ground land connected to thesecond ground plane, a second transmission line, and a second signalland connected to the second transmission line, wherein the secondground land and the second signal land are located on a surface opposingthe first board and are respectively opposed to the first ground landand the first signal land; and a conduction member connecting the firstground land to the second ground land, wherein the first signal land andthe second signal land are connected by capacitance coupling withoutusing any conductor, wherein the first board further includes aradiation element connected to the first signal land with the firsttransmission line interposed between the radiation element and the firstsignal land, and wherein a high frequency circuit element is mounted onthe second board and is connected to the second signal land with thesecond transmission line interposed between the high frequency circuitelement and the second signal land.
 2. The high frequency moduleaccording to claim 1, wherein the first board further includes a firststub on a connection portion between the first transmission line and thefirst signal land.
 3. The high frequency module according to claim 1,wherein the second board further includes a second stub on a connectionportion between the second transmission line and the second signal land.4. The high frequency module according to claim 1, wherein the firstboard further includes a first protection film on a surface opposing thesecond board, such that the first ground land is exposed and the firstsignal land is covered, and wherein the second board further includes asecond protection film on a surface opposing the first board, such thatthe second ground land is exposed and the second signal land is covered.5. A board equipped with an antenna comprising: a first dielectricsubstrate; a radiation element on the first dielectric substrate; afirst signal land on the first dielectric substrate and connected to theradiation element; a first ground plane in or on the first dielectricsubstrate; a first ground land connected to the first ground plane, thefirst ground land and the first signal land being on a same surface ofthe first dielectric substrate; and a first protection film on thesurface of the first dielectric substrate having the first signal land,such that the first signal land is covered and the first ground land isexposed.
 6. A high frequency circuit board comprising: a seconddielectric substrate; a high frequency circuit element on the seconddielectric substrate; a second signal land on the second dielectricsubstrate and connected to the high frequency circuit element; a secondground plane in or on the second dielectric substrate; a second groundland connected to the second ground plane, the second ground land andthe second signal land being on a same surface of the second dielectricsubstrate; and a second protection film on the surface of the seconddielectric substrate having the second signal land, such that the secondsignal land is covered and the second ground land is exposed.
 7. Thehigh frequency module according to claim 2, wherein the second boardfurther includes a second stub on a connection portion between thesecond transmission line and the second signal land.
 8. The highfrequency module according to claim 2, wherein the first board furtherincludes a first protection film on a surface opposing the second board,such that the first ground land is exposed and the first signal land iscovered, and wherein the second board further includes a secondprotection film on a surface opposing the first board, such that thesecond ground land is exposed and the second signal land is covered. 9.The high frequency module according to claim 3, wherein the first boardfurther includes a first protection film on a surface opposing thesecond board, such that the first ground land is exposed and the firstsignal land is covered, and wherein the second board further includes asecond protection film on a surface opposing the first board, such thatthe second ground land is exposed and the second signal land is covered.